Method and apparatus for reviewing defects

ABSTRACT

A method of inspecting defects of a sample on a movable table includes a first step for, on a basis of position information of the defects which is previously detected by an other inspection system, driving the table so that the defects come into a viewing field of an optical microscope having a focus which is adjusted, a second step for re-detecting the defects to obtain a first detection result, a third step for correcting the position information of defects on a basis of position information of the re-detected defects, and a fourth step for reviewing the defects whose position information is corrected to obtain a second detection result. At the second step, re-detecting is performed using reflection light or scattered light from the sample which passes an optical filter which includes a light shielding portion and a light transmitting portion.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No.12/573,479, filed Oct. 5, 2009, which, in turn, is a continuation ofSer. No. 11/668,510, filed Jan. 30, 2007 (now U.S. Pat. No. 7,601,954),the contents of which are incorporated herein by reference.

The present application claims priority from Japanese Patent ApplicationNo. JP 2006-057471 filed on Mar. 3, 2006, the content of which is herebyincorporated by reference into this application.

TECHNICAL FIELD OF THE INVENTION

The present invention relates to a defect reviewing technique forreviewing defects occurring in semiconductor manufacturing processes.More particularly, a technique effectively applied to a method and anapparatus for reviewing defects using an electron microscope and anX-ray analyzer and the like.

BACKGROUND OF THE INVENTION

For example, in semiconductor manufacturing processes, existence offoreign matters (particles) or defects (hereinafter, referred to asdefects, which include foreign matters and pattern defects) on asemiconductor substrate (wafer) causes incomplete insulation betweenwires and other failures such as short-circuit and the like. Further,along with miniaturization of circuit patterns, finer defects causeincomplete insulation of capacitors and destruction of gate oxide films.These defects come from various causes including ones occurring frommoving parts of a transportation apparatuses, ones emitted from humanbodies, ones generated by reaction of process gas in processingapparatuses, ones mixed in chemicals and materials, and others, and aremixed in various states. Accordingly, it is necessary to detect defectsoccurring in the manufacturing processes, pinpoint the occurring sourceof defects, and prevent defects from being outflowing.

In the prior art, as the method for finding out the causes of defects, amethod has been employed where the defect position is first identifiedby a defect inspection system, and the defect concerned is reviewed indetail by use of a SEM (Scanning Electron Microscope) and the like andclassified, and compared with the database and the cause of the defectis estimated.

Herein, the defect inspection system includes: an optical particleinspection system that implements dark-field illumination on the surfaceof a semiconductor substrate by a laser beam, detects scattering lightfrom a defect, and identifies the defect position; and an optical visualinspection system or a SEM inspection system with a lamp light or alaser beam or an electron ray as its illumination light, which detects alight-field optical image of a semiconductor substrate, compares thiswith reference information and thereby identifies the defect position onsemiconductor substrate.

These reviewing methods are disclosed in Japanese Patent ApplicationLaid-Open Publication No. 2001-133417, Japanese Patent ApplicationLaid-Open Publication No. 2003-7243, Japanese Patent ApplicationLaid-Open Publication No. 5-41194, and Japanese Patent ApplicationLaid-Open Publication No. 2005-156537.

Meanwhile, when a defect of the semiconductor substrate is to bedetected by use of the optical particle inspection system, in order toincrease the throughput of the inspection, the semiconductor substrateis scanned by a laser beam of a large spot size for detection. For thisreason, the precision of the detect position obtained from the spotposition of the laser beam that scans the semiconductor substrate willinclude large error components.

When a defect is reviewed in detail by the SEM on the basis of theposition information of the defect including such error components,there is a case where reviewing is made with a further highermagnification (=small viewing field) than the magnification of theoptical system of the optical particle inspection system, andaccordingly, the defect to be reviewed may not come into the viewingfield of the SEM. In order to make the detect of the reviewed objectcome into the viewing field of the SEM, the detect is searched for whilethe viewing field of the SEM is moved, but the viewing field is small,therefore, it takes much time. And consequently, the throughput of theSEM reviewing declines, and it take much time to analyze the defect,which is a problem.

In order to solve the above problem, in the Japanese Patent ApplicationLaid-Open Publication No. 2001-133417, Japanese Patent ApplicationLaid-Open Publication No. 2003-7243, Japanese Patent ApplicationLaid-Open Publication No. 5-41194, and Japanese Patent ApplicationLaid-Open Publication No. 2005-156537 mentioned previously, a parallelarrangement of the SEM and an optical microscope is disclosed. However,in order to detect defects precisely by the optical microscope, it isnecessary to focus the optical microscope, but when a stage is employedso as to move up and down the semiconductor substrate for focusing, amovement stage in the vertical direction is additionally arranged to astage that can move in the horizontal direction at a high speed and withhigh precision, the apparatus will become expensive and massive, whichis another problem.

SUMMARY OF THE INVENTION

The present invention provides, according to a method and an apparatusfor reviewing defects in detail by a SEM where the reviewed defects aredetected by an optical particle inspection system or an optical visualinspection system, the method and apparatus capable of making a defectof a reviewed object come into the viewing field of the SEM or the like,and making the apparatus scale compact.

The above and other novel characteristics of the present invention willbe apparent from the description of this specification and theaccompanying drawings.

The typical ones of the inventions disclosed in this application will bebriefly described as follows.

In the present invention, there is provided a method for reviewingdefects of a sample, including the following steps. A first step for, onthe basis of position information of defects on the sample placed on atable that can move in an X-Y plane, the position information of defectsbeing detected and obtained by inspecting the sample by other inspectionsystem beforehand, driving the table and making the defects come intothe viewing field of an optical microscope, and adjusting the focus ofthe optical microscope onto the sample; a second step for re-detectingthe defects by the optical microscope; a third step for correcting theposition information of defects on the basis of the position informationof defects re-detected at the second step; and a fourth step forreviewing the defects whose position information is corrected at thethird step by an electron microscope. At the first step, adjusting thefocus of the optical microscope onto the sample is made by moving a partof or whole of the optical microscope in the normal line direction ofthe sample surface.

Further, in the present invention, there is provided a method forreviewing defects of a sample, including the following steps. A stepfor, by use of an image obtained by light-field illuminating on a sampleplaced on a table that can move in an X-Y plane and photographing thesample by an optical microscope, adjusting and aligning the position androtation direction of the sample in the X-Y plane; a step for, on thebasis of position information of defects on the sample aligned, whereinthe position information of defects is detected and obtained byinspecting the sample by other inspection system beforehand, driving thetable and making the defects come into the viewing field of the opticalmicroscope, and adjusting the focus of the optical microscope onto thesample; a step for dark-field illuminating on the defects andre-detecting the defects by use of the optical microscope with theadjusted focus to obtain the position information of the defects in theX-Y plane; a step for correcting the position information of defectsdetected and obtained by inspecting the sample by the other inspectionsystem beforehand on the basis of the position information of there-detected defects in the X-Y plane; and a step for driving the tableso as to make the defects of the sample whose position information iscorrected come into the viewing field of an electron microscope, andreviewing the defects by an electron microscope. In addition, in thestep for adjusting the focus of the optical microscope onto the sample,adjusting the focus of the optical microscope onto the sample is made bymoving a part of or whole of the optical microscope in the normal linedirection of the sample surface.

Furthermore, according to the present invention, there is provided anapparatus for reviewing defects of a sample, including the followingmeans. An optical microscope means that, by use of a positioninformation of defects on a sample detected by other defect inspectionsystem beforehand, re-detects the defects and has a light-fieldillumination optical system and a dark-field illumination opticalsystem, a table means that loads the sample and can move on an X-Yplane, focus position adjusting means that adjusts the focus position ofthe optical microscope onto the sample placed on the table means,position information correcting means that corrects position informationof defects detected by the other defect inspection system beforehand onthe basis of the position information of defects on the sampleredetected by the optical microscope whose focus position is correctedby the focus position adjusting means, and electronic microscope meansthat reviews the defects whose position information is corrected by theposition information correcting means on the sample transferred by thetable means. The focus position adjusting means adjusts the focusposition of the optical microscope onto the sample placed on the tablemeans by moving a part of or whole of the optical microscope in thenormal line direction of the sample surface.

The effects obtained by typical aspects of the present invention will bebriefly described below.

According to the present invention, when defects detected by the opticaldefect inspection system is reviewed in detail by the SEM or the like,it is possible to make defects of reviewed objects come precisely intothe viewing field of the SEM or the like, and accordingly, it ispossible to increase the throughput of the detailed inspection ofdefects using the SEM or the like. Further, it is possible to reduce thescale of the stage to load samples to be inspected, and consequently, itis possible to make the apparatus inexpensive and compact.

These and other objects, features and advantages of the invention willbe apparent from the following more particular description of preferredembodiments of the invention, as illustrated in the accompanyingdrawings.

BRIEF DESCRIPTIONS OF THE DRAWINGS

FIG. 1 is a view showing an example of a structure of a defect reviewingapparatus according to a first embodiment of the present invention;

FIG. 2 is a detail view showing a dark-field illuminating unit in thefirst embodiment of the present invention;

FIG. 3A is a detail side view showing a coherency reducing unit in thefirst embodiment of the present invention;

FIG. 3B is a detail front view showing the coherency reducing unit inthe first embodiment of the present invention;

FIG. 4 is a detail view showing another example of a coherency reducingunit in the first embodiment of the present invention;

FIG. 5 is a detail view showing an epi-mirror in the first embodiment ofthe present invention;

FIG. 6 is a detail view showing a zoom lens in the first embodiment ofthe present invention;

FIG. 7 is a detail view showing an electron microscope in the firstembodiment of the present invention;

FIG. 8A is a view showing an image acquired by the dark-field detectionmethod of the optical microscope in the first embodiment of the presentinvention;

FIG. 8B is a view showing a defect displacement calculation image on thebasis of an image acquired by the dark-field detection method of theoptical microscope in the first embodiment of the present invention;

FIG. 9 is a view showing a defect reviewing sequence in the firstembodiment of the present invention;

FIG. 10 is a detail view showing a height detecting system in the firstembodiment of the present invention;

FIG. 11A is a view showing a Z-position calculation sequence in thefirst embodiment of the present invention;

FIG. 11B is a view showing an example of a Z-position calculatingprocess;

FIG. 12 is a view showing divisions of automatic defect classificationin the first embodiment of the present invention;

FIG. 13 is a detail view showing another example of a rhombicillumination mirror in the first embodiment of the present invention;

FIG. 14 is a detail view showing another example of an opticalmicroscope in a defect reviewing apparatus according to a secondembodiment;

FIG. 15 is a detail view showing another example of an opticalmicroscope in a defect reviewing apparatus according to a thirdembodiment;

FIG. 16A is a detail cross sectional view showing an optical filter in adefect reviewing apparatus according to a third embodiment;

FIG. 16B is a detail top view showing an optical filter in the defectreviewing apparatus according to the third embodiment; and

FIG. 17 is a detail view showing another example of an opticalmicroscope in a defect reviewing apparatus according to a fourthembodiment.

DESCRIPTIONS OF THE PREFERRED EMBODIMENTS

Hereinafter, embodiments of the present invention will be described indetail with reference to the accompanying drawings. Note that componentshaving the same function are denoted by the same reference symbolsthroughout the drawings for describing the embodiment, and therepetitive description thereof will be omitted.

(First Embodiment)

With reference to FIG. 1 to FIG. 13, a defect reviewing method and anexample of an apparatus thereof according to a first embodiment of thepresent invention are explained hereinafter.

FIG. 1 is a view showing an example of the structure of a defectreviewing apparatus according to the first embodiment of the presentinvention. The defect reviewing apparatus according to the presentembodiment is an apparatus for reviewing defects occurring inmanufacturing processes, in device manufacturing processes where circuitpatterns are formed on a substrate such as a semiconductor device andthe like, and is structured of a sample 1 to be inspected, a sampleholder 2 that holds the sample 1, a stage 3 that can move the sampleholder 2 and move the entire surface of the sample 1 to the portionunder a microscope, a vacuum chamber 4, a scanning electron microscope(hereinafter referred to as SEM) 5, an optical microscope (hereinafterreferred to as OM) 6, height detecting system 7, a control system 8, auser interface 9, a data base 10, and a network 11 for connecting to ahost system.

Further, the OM 6 comprising a dark-field illuminating unit 601, acoherency reducing unit 602, an epi-mirror 603, an integrated rhombicmirror 604, a detection optical system 605, a mirror 606, a half mirror607, an optical filter 608, a zoom lens 609, a detector 610, alight-field illuminating unit 611, a vacuum shutout glass 612, aZ-movement mechanism (including bellows) 613, and lenses not illustratedtherein. Furthermore, the stage 3, the vacuum chamber 4, the SEM 5, theOM 6, the height detecting system 7, the user interface 9, the data base10, and the network 11 are connected to the control system 8.

In the defect reviewing apparatus structured as above, especially, theOM 6 has a function to re-detects (hereinafter referred to also asdetects) the position of defects on the sample 1 detected by an opticaldefect inspection system, and the Z-movement mechanism 613 and theheight detecting system 7 and the like have a function as focusing meansarranged on the OM 6 for focusing on the sample 1, and the controlsystem 8 and the like has a function as position correcting means forcorrecting position information of defects on the basis of positioninformation of defects re-detected by the OM 6, and the SEM 5 has afunction to review defects whose position information is corrected bythe control system 8 and the like, and the structure is so made thatwhen focusing is carried out in the OM 6, the illumination position anddetection position of the OM 6 are not changed to the sample 1.

Hereinafter, details of the respective units are explained withreference to FIG. 2 to FIG. 13.

FIG. 2 shows details of the dark-field illuminating unit 601. Thedark-field illuminating unit 601 comprises an illumination light source6011, a wavelength plate 6012 which adjusts the polarization directionof illumination light, and a shutter 6013 which controls ON/OFF ofradiation of illumination light.

The illumination light source 6011 is a laser oscillator or a lamphouse. The laser oscillator can use visible laser of wavelength 532 nmand 488 nm, 405 nm and the like, ultraviolet laser of wavelength 355 nmand the like, deep ultraviolet laser of wavelength 266 nm and 199 nm andthe like, and multiple wavelength laser, and either continuousoscillation laser or pulse oscillation laser can be used. Further, aslamp light, Hg lamp and Xe lamp may be used. With regard to theselection method of these, the visible laser and the lamp can realize astable and inexpensive apparatus, meanwhile the short wavelength lasercan realize an apparatus with a high defect detecting sensitivity.

Next, the coherency reducing unit 602 is used to reduce the coherency oflaser and the like and stabilize detected signals. The function of thiscoherency reducing unit 602 is to reduce spatial coherency and timecoherency, and one example is shown in FIG. 3. FIG. 3A is a side view ofthe coherency reducing unit 602, and FIG. 3B is a front view thereof.The coherency reducing unit 602 comprises a scattering plate 6021, and arotation motor 6022 for the scattering plate. The scattering plate 6021rotates around the motor shaft of the rotation motor 6022. When lightemitted from the dark-field illuminating unit 601 goes through thescattering plate 6021, it is possible to reduce coherency. Meanwhile,although the example with the scattering plate is shown in the presentembodiment, other means may be employed as long as it changes lightphases spatially per hour. And as shown in FIG. 4, a means where fiberswith different lengths are bundled and thereby changing phases of lightemitted from respective fibers may be employed.

The epi-mirror 603, as shown in FIG. 5, has a function to reflectincoming light to the Z-axis direction. Further, the integrated rhombicmirror 604 is a mirror that collects the light going out from theepi-mirror 603 to the focus position of the detection optical system605, and is arranged in the detection optical system 605. This may be aprism instead of a mirror.

The detection optical system 605 comprises a plurality of lenses, andhas a function to collect lights reflected and scattered from the sample1 and provide an image on the detector 610 via the optical filter 608and the zoom lens 609. Herein, it is preferable that lights coming intothe optical filter 608 are parallel. An advantage of parallel lights isthat there is no change of light path length made by the optical filter608.

The optical filter 608 is a filter that modulates light, and is forexample a polarization plate. However, when an optical filter is notused, a glass plate may be employed instead of a movement mechanism notillustrated therein.

Next, details of the zoom lens 609 are explained hereinafter. A functionof the zoom lens 609 is to change the image formation magnifications ofthe OM 6. The change of the image formation magnifications is used atalignment. For example, the sample 1 held by the sample holder 2 oftenhas displacement in the rotation direction or the X-Y plane direction.Accordingly, it is needed to align the sample 1, but since thedisplacement amount at the first time when the sample 1 is placed islarge, in order to search for texture for alignment, it is necessary tosearch for it in a wide viewing filed. On the other hand, highly precisepositioning is necessary for defect reviewing, and highly precisealignment is required accordingly, and alignment by high magnificationreviewing is required. At this moment, the viewing field becomes small,therefore it is preferable to have multiple magnifications.

As shown in FIG. 6, the zoom lens 609 comprises lenses 6091, 6092, 6093,and a movement mechanism 6094 that moves the respective lenses in theZ-direction. In the present embodiment, in order to changemagnifications without changing the distance between the sample 1 andthe detector 610, the distances among the lenses 6091, 6092, 6093 arechanged, and thereby changing magnifications.

The detector 610 is, for example, a two-dimensional CCD camera. As itsperformance, it may have sensitivity to the wavelength of illuminationlight source of the light-field illuminating unit 6011, and may have aTDI (Time Delay Integration) function, and a CCD unit of rear surfaceradiation type may be employed too. In the case having the TDI function,highly sensitive detection of fine light is feasible, therefore it isadvantageous with a small illumination light amount, meanwhile theadvantage of using the CCD of rear surface radiation type is that highlysensitive detection is feasible in wavelength ranges of ultraviolet rayand deep ultraviolet ray. Further, in the case of a structure where thesample 1 is scanned by illumination light at photographing, aone-dimensional CCD sensor may be employed. Further, a color camera mayalso be employed. An advantage in using a color camera is that colorimages of the sample 1 can be obtained, and defects can be identifiedfrom color information of the sample 1.

The SEM 5 is described with reference to FIG. 7. The SEM 5 comprises anelectron source 501 that generates primary electron, an accelerationelectrode 502 that accelerates the primary electron, a focusing lens503, a deflector 504 that deflects the primary electron fortwo-dimensional scanning, an objective lens 505 that focuses the primaryelectron onto the sample 1, a secondary electron detector 506 thatdetects secondary electron generated from the sample 1, and a reflectionelectron detector 507 that detects reflection electron generated fromthe sample 1. Meanwhile, two or more of the detectors 506 and 507respectively may be arranged.

Operations in the structure of the defect reviewing apparatus shown inFIG. 1 are explained hereinafter. First, the sample 1 is transferredonto the sample holder 2 in the vacuum chamber 4 via a load lock chambernot illustrated. Then, the sample 1 is moved to the viewing fieldposition of the OM 6 by control of the stage 3. At this moment, there isa possibility that the sample 1 is displaced from the focus position ofthe OM 6. When the height of the sample 1 is displaced from the focusposition, the detection optical system 605 is moved in Z-direction byuse of the Z-movement mechanism 613 so that the sample 1 is set onto thefocus position of the OM 6. At this moment, since the integrated rhombicmirror 604, the mirror 606, the half mirror 607, the optical filter 608,the zoom lens 609, and the detector 610 are arranged in the detectionoptical system 605, they move together with the detection optical system605. Meanwhile, the method to determine the movement amount in theZ-direction is described later.

After the Z-position of the detection optical system 605 is adjusted,alignment of the sample 1 is performed. The alignment is mainly forcorrecting the parallel movement amount and rotation amount of thesample 1 in the X-Y plane, and aligning the coordinate system of aninspection system and the coordinate system of the defect reviewingapparatus according to the present embodiment. As the method ofalignment, the image of the sample 1 is acquired by the OM 6, and theacquired image is processed and the position to be referred iscalculated. At this moment, in the case of a sample where circuitpatterns are not formed, alignment is made with the edge portion of theoutline of the sample 1, and in the case of a sample where circuitpatterns are formed, image processing is performed with circuit patternexisting at a predetermined position.

The alignment is carried out by use of the image acquired by light-fielddetection method. In the light-field detection, illumination light isemitted from the light-field illuminating unit 611, and reflected by themirror 606 and the half mirror 607, and radiated onto the sample 1. Thereflection light from the sample 1 is reflected by the mirror 606 andthe half mirror 607, and provide an image on the detector 610 by thezoom lens 609. Herein, the light-field illuminating unit 611 is, forexample, a lamp illumination. In addition, in the light-field detectionaccording to the present embodiment, the optical filter 608 is changedwith a glass plate of the same thickness by use of a movement mechanismnot illustrated. When the alignment is carried out with the edge of theoutline of the sample 1, several images of the positioning point (notchor orientation flat in the case when the sample 1 is a wafer) of thesample 1 and profile are acquired and the process is carried out.

After the alignment, according to the position information of thedefects outputted from the defect inspection system, the defect positionis moved to the viewing field position of the OM 6, and images ofdefects are acquired by the dark-field detection method of the OM 6. Atthis moment, when the height of the sample 1 at each defect position isdisplaced from the focus position of the OM 6, focusing is carried outby the method mentioned above.

Here, the dark-field detection method is explained. The dark-fielddetection method is applied mainly to a sample where circuit patternsare not formed. At the dark-field detection, first, illumination lightis emitted from the dark-field illuminating unit 601. The illuminationlight may be either laser light or lamp light, but illumination can bemade brighter with the laser light, therefore it is preferable to employthe laser light. However, in the case of a sample 1 on which a film of ahigh reflection ratio such as an aluminum film is applied, theillumination may be low, therefore the lamp light may be employed.

The coherency of the light emitted from the dark-field illuminating unit601 is reduced by the coherency reducing unit 602. This is mainly forreducing speckle of laser light, and it may be omitted in the case touse lamp light. The light passing the coherency reducing unit 602 goesthrough the vacuum shutout glass 612, and goes into the vacuum chamber4, and is bent to the Z-direction by the epi-mirror 603. The lightreflected by the epi-mirror 603 is radiated onto the sample 1 at thefocus position of the detection optical system 605 by the integratedrhombic mirror 604. Light reflected and scattered from the sample 1 arecollected by the lens of the detection optical system 605, and reflectedby the mirror 606 and the half mirror 607, and goes into the opticalfilter 608. The light passing the optical filter 608 goes through thezoom lens 609 and an image is provided at the photographing position ofthe detector 610, and is converted into digital signals by the detector610, and sent to the control system 8.

The images acquired by the dark-field detection method of the OM 6 arestored into the control system 8 as a gray image or a color image asshown in FIG. 8A. The control system 8 calculates the viewing field areaof the SEM 5 and the displacement amount of the defect position as shownin FIG. 8B, and registers the displacement amount as a coordinatecorrection value. With regard to the method of calculating thedisplacement amount, for example, with the center of viewing field ofthe SEM 5 as the center of the image, the number of pixels between thecoordinate of center of gravity of defect position in the image and thecenter of the image is calculated, and the number of pixels ismultiplied by the dimension of the pixel image. Thereafter, the sample 1is moved by the stage 3 so that the defect comes in the viewing fieldarea of the SEM 5 by use of the coordinate correction value, and thedefect is reviewed by the SEM 5. The reviewed defect image is sent tothe control system 8, and used for display to the user interface 9 orregistration to the database 10, or automatic defect classificationprocess or the like.

Next, operations of the SEM 5 are described with reference to FIG. 7.Primary electron emitted from the electron source 501 is accelerated toa desired speed by the acceleration electrode 502, and by the focusinglens 503 and the objective lens 505, converged onto the sample 1. Fromthe sample 1, secondary electron and reflection electron triggered bythe primary electron are emitted. The emitted electron is detected bythe secondary electron detector 506 and the reflection electron detector507, and converted into digital signals by a photoelectric converter andan ND converter not illustrated therein. The primary electron isdeflected by the deflector 504, and the two-dimensional area on thesample 1 is scanned, and the signal of the area is obtained. Theobtained signal is digitalized, and sent to the control system 8, anddesigned as an image therein. Meanwhile, the focus position of the SEM 5may be adjusted at each position, or the Z-position informationcalculated at reviewing of the OM 6 may be stored, and the focusposition for reviewing by the SEM 5 may be calculated and used.

The flow of the defect reviewing is explained with reference to FIG. 9.First, the sample 1 is aligned (S1301). This is the alignment by the OM6 as mentioned previously. Next, according to the position informationof the defect detected by the defect inspection system, the defect to bereviewed on the sample 1 is moved to the viewing field of the OM 6(S1302). The OM 6 is moved and focusing is performed (S1303). The defectposition is searched in the image acquired by the OM 6 (S1304), and ifthe defect is detected (S1305—Yes), the displacement amount between thedefect detected position detected by the OM 6 and the viewing fieldposition of the SEM 5 is calculated (S1306). On the basis of thedisplacement amount, the position information of the defect is corrected(S1307), and the corrected defect position is moved to the viewing fieldof the SEM 5, and reviewing is carried out (S1308). At this moment,information reviewed is sent to the control system 8. Next, when it isnot necessary to review other defect (S1309—No), the reviewing ends(S1310), and when it is necessary to review other defect (S1309—Yes),position information of the defect to be reviewed is acquired (S1311),and the procedure goes back to the sequence (S1302) to move the defectto the OM 6 mentioned above and the process is carried out. Meanwhile,if the defect cannot be detected in the defect detection sequencementioned above (S1305—No), since the defect position may be displacedto the out of the viewing field, the portion around the viewing field ofthe OM 6 may be searched. When the portion around the viewing field issearched (S1312—Yes), the sample 1 is moved by the size corresponding tothe viewing field (S1313), and the processes from the abovementioneddefect searching sequence (S1304) are carried out. And, when the portionaround the viewing field is not searched (S1312—No), the process iscarried out according to the sequence (S1309).

Next, the method of calculating the Z-position is explained withreference to FIG. 10. FIG. 10 shows the structure of the heightdetecting system 7, which comprising an illumination light source 701,an illumination light focusing lens 702, a detection light focusing lens703, and a detector 704. In further detail, the illumination lightsource 701 is, for example, a laser oscillator or a lamp house, and thedetector 704 is, for example, a CCD camera or a CCD linear sensor.

Operations of the height detecting system 7 are explained. Light emittedfrom the illumination light source 701 is collected onto the sample 1 bythe illumination light focusing lens 702. In the sample 1, light isreflected in the direction corresponding to the incident angle to thesample 1. The reflection light is collected to the detector 704 via thedetection light focusing lens 703. As the method of calculating theZ-position, first, the light detection position of the detector 704 atthe reference height of the sample 1 is memorized. Next, when the heightof the sample 1 changes, the light detection position in the detector704 moves, and accordingly, by previously measuring the relation betweenthe movement amount of the light detection position (number of pixels ofthe detector 704) and the change amount of the height of the sample 1,it is possible to calculate the height from the movement amount.

Meanwhile, in the case where laser light is used for illumination, sincethe light collecting efficiency is good, there is an advantage that ahighly precise detection is feasible by use of a light source of lowoutput. Further, in the case where lamp light (=light of multiplewavelength) is used, there is an advantage that stable detection isfeasible even on a sample where a transparent film is applied to themost upper surface of the sample 1. This is by averaging effect tofluctuation of film thickness.

Another method of calculating the Z-position is explained with referenceto FIG. 11. FIG. 11 shows a Z-position calculation sequence. This methodis an example using images acquired by the OM 6. First, by use of theZ-movement mechanism 613, the detection optical system 605 is moved tothe lowest point (=a point closest to the sample) (S1401). Next, animage is acquired by the detector 610, and sent to the control system 8(S1402). At this moment, in the case where an image of the edge of thesample is used or the case of a sample where circuit patterns areformed, it is preferable to use the light-field detection method, and inthe case of a sample without circuit patterns, it is preferable to usethe dark-field detection method. After the image is acquired, thedetection optical system 605 is moved one step up by the Z-movementmechanism 613 (S1403). Herein, one step means the unit of resolution fordetecting the Z-position, and equal to the ½ of the focus depth of theOM 6 or less is generally preferable. After the detection optical system605 is moved, if the position of the detection optical system 605 is inthe predetermined movement area (S1404—Yes), then image is acquiredagain (S1402). On the other hand, if the position of the detectionoptical system 605 exceeds the movement area (S1404—No), the proceduregoes to the sequence of the Z-position calculation process (S1405).

An example of the Z-position calculating process is explained. First,the maximum intensity in the image is searched for, and a graph 1411where the Z-position and the maximum intensity are plotted on iscreated. Next, the peak position in the graph 1411 is calculated. Atthis moment, it is preferable to approximate it by a multidimensionalcurve on the basis of measurement point, and calculate the peakposition. And, the Z-position corresponding to the peak position becomesthe position to which the detection optical system should be moved.

Meanwhile, in the example using the abovementioned height detectingsystem 7, the height detecting system 7 is positioned at the position ofthe SEM 5, and the height of the OM 6 is determined from the height ofthe sample 1 at the position of the SEM 5. However, the height detectionsystem 7 may be set at the position of the OM 6, further, it may be setat the positions of both the SEM 5 and the OM 6. When the number of theheight detecting systems 7 is small, it is possible to manufacture aninexpensive apparatus, meanwhile, when height detecting systems 7 areset at both, it is possible to improve the focusing precision.

Next, an example of automatic defect classification is explained withreference to FIG. 12. FIG. 12 shows combinations of the defect detectionresults in the OM 6 and the defect detection results in the SEM 5. Ingeneral, in the case where an optically transparent film is formed onthe most upper surface of sample, defect under the film can be detectedoptically, but its detection is difficult by the SEM. This is becausethe SEM detects secondary electron and reflection electron emitted fromthe sample surface. By use of this nature, classified defects in FIG. 12are obtained. That is, those defects that can be detected by the OM 6and also by the SEM 5 are classified as defects existing on the samplesurface, those defects that can be detected by the OM 6 and but not bythe SEM 5 are classified as defects existing in the film or under thefilm. Further, those defects that cannot be detected by the OM 6 nor theSEM 5 are classified as nuisances of the defect inspection system, thatis, error detection.

In the example explained above, to each defect, the correction amount ofthe defect position is calculated, and at every time, reviewing is madeby the SEM 5, but it may be applied to the case where a plurality ofdefect position correction amounts are registered by the OM 6, and afterthe correction amounts of a plurality of defects or all the defects arecalculated, reviewing is made by the SEM 5. Further, in the case wherethe displacement amount of defect detected by the defect inspectionsystem is considered to be only a parallel movement amount in a fixeddirection and a rotation component in a fixed direction, a correctionequation of positions of all the defects is created from positioncorrection amounts of several (3 points or more) defects, and withoutusing reviewing by the OM 6 but using the calculated positions by thecorrection equation, reviewing may be made by the SEM 5. And in the casewhere there exists an already reviewed defect at the vicinity of defectof the object to be reviewed, the position correction amount of thereviewed defect may be applied as the position correction amount of thedefect of the object to be reviewed. Further, with the correctionequation as initial data, correction equation may be corrected and usedat every time of coordinate correction by the OM 6. Further, in the casewhere the displacement amount of defect position detected by the defectinspection system is estimated to be nearly same value irrespective ofsample, by use of the correction equation of already measured sample,the position of a new sample may be corrected. An advantage of reducingthe number of defects whose correction amounts are calculated as aboveis that the throughput of reviewing work can be improved.

Further, in the case where a beam diameter of beam emitted from thedark-field illuminating unit 601 is large, and the illumination area issufficiently large to the viewing field area, or in the case where theangle of rhombic illumination by the integrated rhombic mirror 604 issmall, in the place of the epi-mirror 603 and the integrated rhombicmirror 604, an integrated prism 621 as shown in FIG. 13 may be employed.This integrated prism 621 reflects incoming light to the sample 1 side,and further rhombically illuminates the sample 1. An advantage of usingsuch an integrated prism 621 is that it is possible to make thestructure simpler than in the case where the epi-mirror 603 and theintegrated rhombic mirror 604 are employed.

Furthermore, in the present embodiment, the case where reviewing is mademainly by use of an electron microscope has been explained, however,besides the electron microscope, the present invention may be applied toan X-ray analyzer or an analyzer using FIB (Focused Ion Beam) and thelike, which can make more detailed reviewing than optical type.

(Second Embodiment)

With reference to FIG. 14, a defect reviewing method and an example ofan apparatus thereof according to a second embodiment of the presentinvention are explained hereinafter.

In the defect reviewing apparatus according to the present embodiment,another example of the OM 6 is explained with reference to FIG. 14. TheOM 6 comprises a dark-field illuminating unit 601, a coherency reducingunit 602, an epi-mirror 631, a detection optical system 605, a mirror606, a half mirror 607, an optical filter 608, a zoom lens 609, adetector 610, a light-field illuminating unit 611, a vacuum shutoutglass 612, a guide rail 632 for moving the detector 610, a origin sensorfor calculate the position of the detector 610, a pulse motor 634 formoving the detector 610, a vacuum shutout glass 635, and lenses notillustrated therein. Meanwhile, the epi-mirror 631 is not necessary tomove along the height change of a sample 1, therefore, it may be fixedonto the detection optical system 605.

In the abovementioned first embodiment, structural componentsaccompanying the detection optical system 605 are moved in theZ-direction and thereby focusing is carried out. However, in the presentembodiment, the detection optical system 605 is fixed, and the detector610 is moved in the Z-direction and thereby focusing is carried out. Thestructure according to the present embodiment does not require to movethe detection optical system 605, therefore there is an advantage thatthe structure of the Z-movement mechanism is made simple. However, sincethe image providing magnification to the detector 610 fluctuates, if themagnification fluctuation becomes a problem, it is necessary to correctthe magnification and the like.

Operations in the structure of the defect reviewing apparatus includingthe OM 6 shown in FIG. 14 are explained. The operations to acquireimages by the light-field detection method and the dark-field detectionmethod are same as those in the abovementioned first embodiment,Therefore, herein, a method of focusing and a method of correctingmagnification are described.

First, as a method of measuring the height of the sample 1, theabovementioned height detecting system 7 may be employed. At thismoment, if the distance between the sample 1 and a main flat surface onthe object side of the detection optical system 605 is defined as “a”,and the distance between a main flat surface on the image side of thedetection optical system 605 and the light receiving surface of thedetector 610 is defined as “b”, and the focus distance of the detectionoptical system 605 is defined as “f”. From the information acquired fromthe abovementioned height detection system 7, the “a” is already known,and the focus distance “f” is also already known, therefore from therelation equation of (Equation 1), the value of “b” can be calculated.Accordingly, when the detector 610 is moved to the position to becomethe distance of “b”, focus adjusting is completed.1/a+1/b=1/f  (Equation 1)

The method of moving the detector 610 is, for example, the method ofmoving it by use of the pulse motor 634 along the guide rail 632 in theZ-direction. As for the movement amount by the pulse motor 634, thenumber of pulses from an origin sensor 633 may be calculated. At thismoment, image providing magnification “M” becomes as shown in (Equation2). And when the magnification at the reference position is defined asM0, the value “k” to be calculated by (Equation 3) becomes themagnification fluctuation amount. Accordingly, by multiplying thedisplacement amount of the defect position calculated from image by themagnification fluctuation amount “k”, it is possible to calculate theposition correction amount after magnification correction.M=b/a  (Equation 2)k=M/M0  (Equation 3)

Meanwhile, in the case when the height detecting system 7 is not used,in place of image acquisition by moving the detection optical system 605explained in the above described first embodiment, by moving thedetector 610 to acquire image, focus adjusting made from detected imageis feasible. In this case, the position of the detector 610 iscalculated by the number of pulses from the origin sensor 633, and thecalculated value is substituted to the value of the abovementioned “b”and the magnification “M” is calculated.

(Third Embodiment)

With reference to FIG. 15 and FIG. 16, a defect reviewing method and anexample of an apparatus thereof according to a third embodiment of thepresent invention are explained hereinafter.

In the defect reviewing apparatus according to the present embodiment,another example of the OM 6 is described with reference to FIG. 15. TheOM 6 comprises a laser illuminating unit 641, a coherency reducing unit602, a lamp illuminating unit 642, a mirror 643, a half mirror 644, adetection optical system 645, an optical filter 646, a zoom lens 609, adetector 610, a Z-movement mechanism 613, and lenses not illustratedtherein. The present embodiment is an example where onlyepi-illumination is arranged as illumination light path, and has anadvantage that the structure can be made simple.

Operations in the structure of the defect reviewing apparatus includingthe OM 6 shown in FIG. 15 are explained. First, the method of acquiringa dark-field image by laser light is explained. At the moment of laserillumination, the mirror 643 is excluded from the laser illuminationlight path by use of a mechanism not illustrated therein. Light emittedfrom the laser illuminating unit 641 goes through the coherency reducingunit 602 and is reflected to the sample 1 side by the half mirror 644arranged in the detection optical system 645, and radiated onto thesample 1. Reflection light and scattered light from the sample 1 aredetected by the detection optical system 645, and the light passing theoptical filter 646 provides an image onto the detector 610 by the zoomlens 609.

Here, the optical filter 646 is set at the pupil position of thedetection optical system 645, and is a filter of the shape shown in FIG.16. FIG. 16A is a cross sectional view of the optical filter 646, andFIG. 16B is a top view thereof. The optical filter 646 is a filter thathas a light shielding portion at the portion around the optical axisthereof, and let the light positioned between the light shieldingportion and the pupil outline pass through. The light shielding portionis set at the area that shields the normal reflection light of thesample 1. Further, the light transmitting portion is a glass plate or apolarization plate. When the light transmitting portion is a glassplate, normal dark-field detection is available, and when the lighttransmitting portion is a polarization plate, dark-field polarizationdetection is available.

Further, when light-field detection is carried out, the optical filter646 may be excluded from the light path by a mechanism not illustratedtherein. Further, when reviewing is performed by lamp illumination, themirror 643 may be inserted into the light path, and the light emittedfrom the lamp illuminating unit 642 may be reflected by the mirror 643for use.

(Fourth Embodiment)

With reference to FIG. 17, a defect reviewing method and an example ofan apparatus thereof according to a fourth embodiment of the presentinvention are explained hereinafter.

In the defect reviewing apparatus according to the present embodiment,still another example of the OM 6 is explained with reference to FIG.17. The OM 6 herein comprises dark-field illuminating units 601 a and601 b, coherency reducing units 602 a and 602 b, mirrors 651 and 651 b,vacuum shutout glasses 612 a and 612 b, integrated rhombic mirrors 652 aand 652 b, a detection optical system 653, a half mirror 644, an opticalfilter 608, a zoom lens 609, a dichroic mirror 654, detectors 610 a and610 b, a light-field illuminating unit 611, a Z-movement mechanism 613,and lenses not illustrated therein.

Here, subscripts “a” and “b” in the present embodiment show parts thatcorrespond to different wavelengths. That is, the dark-fieldilluminating units 601 a and 601 b radiate lights of differentwavelengths respectively. For example, the dark-field illuminating unit601 a radiates laser light of wavelength 532 nm, and the dark-fieldilluminating unit 601 b radiates laser light of wavelength 405 nm, andnot limited to the abovementioned wavelengths, but a combination ofother wavelengths may be used. The dichroic mirror 654 has theperformance to separate the different wavelengths. Further, theintegrated rhombic mirrors 652 a and 652 b have structures whereradiation angles to the sample 1 are different. That is, the integratedrhombic mirror 652 a radiates light to the sample 1 at angle α, and theintegrated rhombic mirror 652 b radiates light to the sample 1 at angleβ, and, α and β are different angles. Further, the integrated rhombicmirrors 652 a and 652 b are arranged in the detection optical system653. And, according to the movement of the detection optical system 653in the Z-direction, the integrated rhombic mirrors 652 a and 652 b move.The present embodiment is an example to be used in the case when thereare differences in defect detecting performance due to differences inillumination angles.

Operations in the structure of the defect reviewing apparatus includingthe OM 6 shown in FIG. 17 are explained. The light-field detectionmethod and the height detection method are same as those in theabovementioned third embodiment. Therefore, here, a dark-field detectionmethod is explained.

Lights emitted from the dark-field illuminating units 601 a and 601 brespectively pass the coherency reducing units 602 a and 602 b, and arereflected to the sample 1 side by the mirrors 651 a and 651 b. Thereflected lights are radiated onto the sample 1 by the integratedrhombic mirrors 652 a and 652 b. The lights reflected and scattered fromthe sample 1 are collected by the detection optical system 653, and thelight passing the optical filter 608 provides an image on the detectors610 a and 610 b by the zoom lens 609. At this moment, wavelengths areseparated by the dichroic mirror 654, and the reflected and scatteredlights by the lights radiated at the different illumination angles aredetected by the respectively different detectors 610 a and 610 b.Signals obtained by the detectors 610 a and 601 b are sent to thecontrol system 8 where the defect detection process is carried out.

Meanwhile, the present embodiment was explained with the example wheredefect detections by different illumination angles are carried outsimultaneously. However, when there is room in defect detection time,detections may be carried out by changing illumination angles in series.In this case, only one set of the detector 610 may work. Further, in thepresent embodiment, the example where two kinds of illumination anglesare used was explained. However, the number of kinds of the illuminationangles may be increased as necessity.

In the foregoing, the invention made by the inventors of the presentinvention has been concretely described based on the embodiments.However, it is needless to say that the present invention is not limitedto the foregoing embodiments and various modifications and alterationscan be made within the scope of the present invention.

The invention may be embodied in other specific forms without departingfrom the spirit or essential characteristics thereof. The presentembodiment is therefore to be considered in all respects as illustrativeand not restrictive, the scope of the invention being indicated by theappended claims rather than by the foregoing description and all changeswhich come within the meaning and range of equivalency of the claims aretherefore intended to be embraced therein.

What is claimed is:
 1. A method for reviewing defects of a samplecomprising the steps of: a first step for, on the basis of positioninformation of defects on a surface of the sample placed on a table thatcan move in an X-Y plane, where the position information of the defectsis previously detected and obtained by inspecting the surface of thesample by an other inspection system, driving the table and making thedefects come into a viewing field on an optical microscope, andadjusting a focus of a detection optical system of the opticalmicroscope onto the surface of the sample; a second step forre-detecting the defects by the optical microscope; a third step forcorrecting the position information of the defects on the basis of theposition information of the defects re-detected at the second step; anda fourth step for reviewing ones of the defects whose positioninformation is corrected at the third step by an electron microscope,wherein, at the second step, re-detecting is performed using reflectionlight or scattered light from the surface of the sample which passes anoptical filter; wherein the optical filter includes a light shieldingportion and a light transmitting portion, and wherein the detectionoptical system includes an integrated mirror arranged in the detectionoptical system in a manner to be moved with the detection optical systemwhen the detection optical system is being moved to adjust its focalposition, and wherein the method further includes receiving illuminationat the integrated mirror from an illumination optical system of theoptical microscope and radiating the received illumination, by theintegrated mirror, onto the surface of the sample at an oblique angle tothe surface of the sample.
 2. The method for reviewing defects of asample according to claim 1, wherein the optical filter is located at apupil position of a detection optical system of the optical microscope.3. The method for reviewing defects of a sample according to claim 1,wherein the optical filter shields and transmits a light path of thereflection light or scattered light.
 4. The method for reviewing defectsof a sample according to claim 1, wherein, in the first step, theoptical microscope is so controlled so that an illumination position anda detection position on the sample by the optical microscope areidentical even when a part of or the whole of the detection opticalsystem of the optical microscope is moved in a normal line direction ofthe sample surface.
 5. The method for reviewing defects of a sampleaccording to claim 1, wherein, in the first step, a change in detectionmagnifications due to movement of a part of or whole of the detectionoptical system of the optical microscope in a normal line direction ofthe sample surface is adjusted by use of a zoom lens of the opticalmicroscope.
 6. The method for reviewing defects of a sample according toclaim 1, wherein, in the second step, the optical microscope radiateslaser light which is emitted from a laser source and whose coherence isreduced onto the sample from an oblique direction.
 7. The method forreviewing defects of a sample according to claim 6, wherein, in thesecond step, the laser light is generated by a UV laser or a DUV laser.8. The method according to claim 1, wherein the step of adjusting thefocus of the detection optical system of the optical microscope isperformed using a focusing mechanism which comprises a part of theoptical microscope, which is configured to move the detection opticalsystem of the optical microscope in a Z direction for focusing, andwhich is separate from the table.
 9. A method for reviewing defects of asample comprising the steps of: a step for, by use of an image obtainedby a light-field illuminating on a surface of the sample placed on atable that can move in an X-Y plane and photographing the sample by anoptical microscope, adjusting and aligning a position and a rotationdirection of the sample in the X-Y plane; a step for, on the basis ofposition information of defects on a surface of the sample aligned,where the position information of the defects is previously detected andobtained by inspecting the surface of the sample by another inspectionsystem, driving the table and making the defects come into a viewingfield of the optical microscope, and adjusting a focus of a detectionoptical system of the optical microscope on the surface of the sample; astep for dark-field illuminating on the defects and re-detecting thedefects by use of the optical microscope with the adjusted focus of thedetection system and obtaining position information of the defects inthe X-Y plane; a step for correcting the position information of thedefects detected and obtained by inspecting the sample by an otherinspection system beforehand on the basis of the position information ofthe re-detected defects in the X-Y plane; and a step for driving thetable so that the defects of the sample whose position information iscorrected come into a viewing field of an electron microscope andreviewing the defects by the electron microscope, wherein there-detecting is performed by reflection light or scattered light fromthe sample which passes an optical filter; and wherein the opticalfilter includes a light shielding portion and a light transmittingportion, and wherein the detection optical system includes integratedmirrors arranged in the detection optical system in a manner to be movedwith the detection optical system when the detection optical system isbeing moved to adjust its focal position, and wherein the method furtherincludes receiving illumination at the integrated mirrors from anillumination optical system of the optical microscope and radiating thereceived illumination by the integrated mirrors onto the surface of thesample at oblique angles to the surface of the sample.
 10. A method forreviewing defects of a sample according to claim 9, wherein the opticalfilter is located at a pupil position of a detection optical system ofthe optical microscope.
 11. A method for reviewing defects of a sampleaccording to claim 9, wherein the optical filter shields and transmits alight path of the reflection light or scattered light.
 12. The methodfor reviewing defects of a sample according to claim 9, wherein, in thestep for obtaining the position information of the defects in the X-Yplane, the defects on the sample are dark-field illuminated from aplurality of directions.
 13. The method for reviewing defects of asample according to claim 12, wherein respective illumination lights fordark-field illumination on the defect on the sample from a plurality ofdirections have different wavelengths.
 14. The method for reviewingdefects of a sample according to claim 9, wherein, in the step forobtaining the position information of the defects in the X-Y plane, theoptical microscope dark-field illuminates the sample with laser lightthat is emitted from a laser source and whose coherence is reduced. 15.The method for reviewing defects of a sample according to claim 14,wherein the laser light is generated by a UV laser or a DUV laser. 16.The method according to claim 9, wherein the step of adjusting the focusof the detection optical system of the optical microscope is performedusing a focusing mechanism which comprises a part of the opticalmicroscope, which is configured to move the detection optical system ofthe optical microscope in a Z direction for focusing, and which isseparate from the table.
 17. A method for reviewing defects of a sampleaccording to claim 9, wherein the integrated mirrors are arranged toradiate the received illumination onto the surface of the sample atdifferent oblique angles from one another.
 18. An apparatus forreviewing defects of a sample comprising: an optical microscope meansthat, by use of position information of defects on a surface of thesample previously detected by an other defect inspection system,re-detects the defects and has a light-field illumination optical systemand a dark-field illumination optical system; a table means that loadsthe sample and can move on an X-Y plane; a focus position adjustingmeans that adjusts a focus position of a detection optical system of theoptical microscope means onto the surface of the sample placed on thetable means; a position information correcting means that correctsposition information of the defects previously detected by the otherdetect inspection system on the basis of the position information of thedefects on the surface of the sample re-detected by the opticalmicroscope means whose focus position is corrected by the focus positionadjusting means; and an electronic microscope means that reviews one ofthe defects whose position information is corrected by the positioninformation correcting means on the sample transferred by the tablemeans, wherein the optical microscope means includes an optical filterwhich shields and transmits reflection light or scattered light from thesurface of the sample, and wherein the detection optical system includesintegrated mirrors arranged in the detection optical system in a mannerto be moved with the detection optical system when the detection opticalsystem is being moved to adjust its focal position, and wherein theintegrated mirrors are configured to receive illumination from anillumination optical system of the optical microscope and to radiate thereceived illumination onto the sample from directions which are obliqueto the surface of the sample.
 19. The apparatus for reviewing defects ofa sample according to claim 18 wherein the optical filter is located ata pupil position of a detection optical system of the opticalmicroscope.
 20. The apparatus for reviewing defects of a sampleaccording to claim 18, wherein the optical filter shields and transmitsa light path of the reflection light or scattered light.
 21. Theapparatus for reviewing defects of a sample according to claim 18,wherein the optical filter includes a light shielding portion on anoptical axis and includes a light transmitting portion outside of thelight shielding portion relative to the optical axis.
 22. The apparatusfor reviewing defects of a sample according to claim 21, wherein thelight transmitting portion comprises a glass plate or a polarizationplate.
 23. The apparatus for reviewing defects of a sample according toclaim 18, wherein the optical microscope means includes a zoom lens andadjusts the change in detection magnifications due to adjusting thefocus position of the detection optical system of the optical microscopemeans on the sample by the focus position adjusting means by use of thezoom lens.
 24. The apparatus for reviewing defects of a sample accordingto claim 18, wherein the dark-field illumination optical system of theoptical microscope means includes a laser source unit and a coherencereducing optical unit, and radiates laser light emitted from the lasersource unit and whose coherence is reduced by the coherence reducingoptical unit onto the sample placed on the table means from obliquedirections.
 25. The apparatus for reviewing defects of a sampleaccording to claim 24, wherein the laser source unit emits UV laser orDUV laser.
 26. The apparatus for reviewing defects of a sample accordingto claim 18, wherein the dark-field illumination optical system of theoptical microscope means performs dark-field illumination on the defecton the sample from a plurality of directions.
 27. The apparatus forreviewing defects of a sample according to claim 26, wherein thedark-field illumination optical system performs dark-field illuminationon the defect on the sample from a plurality of directions with lightswith respectively different wavelengths.
 28. The apparatus according toclaim 18, wherein the focusing position adjusting means comprises afocusing mechanism which comprises a part of the optical microscopemeans, which is configured to move the detection optical system of theoptical microscope means in a Z direction for focusing, and which isseparate from the table means.
 29. The apparatus for reviewing defectsof a sample according to claim 18, wherein the integrated mirrors arearranged to radiate the received illumination onto the sample atdifferent oblique directions to one another.